Abstract:The mineral flotation wastewater containing residual alkyl xanthates have to be strictly controlled because of its stench, biotoxicity, stable in the pH conditions of neutral or alkaline, and greatly influence on mineral separation indexes when residual in reuse water. Treatment with the proposed electrocatalytic internal micro-electrolysis (ECIME) which cooperates the characteristics of electrochemical and internal micro-electrolysis (IME) is an effective approach to remove alkyl xanthates from wastewater. Therefore, the degradation characteristics, reaction mechanism and pathways of this pollutant toward the remediation technology must be considered deeply. In this work, butyl xanthate (BX) was used as the template of pollutant, electrochemical characterization and spectroscopy analysis methods was conducted to explode this key point. Cyclic voltammetric (CV) indicates that BX can be generated redox reaction directly at the carbon microelectrode and degraded in anode and cathode chamber of the electrolysis cell. The effects of repolarization particle electrode and IME reduce the dependence of BX decomposition on low pH and can realize high degradation efficient in the neutral or alkaline conditions. The dominant degradation mechanism of BX in ECIME system is the electrocatalytic redox directly and mineralization by ?OH indirectly which generates in situ. The main pathways of BX in ECIME system are followed by BX, dixanthogen→N-butyl alcohol or diisobutyl carbonate, CS2→organic acid, H2CO3→H2O, CO2, SO42-. The further degradation N-butyl alcohol or diisobutyl carbonate should be the controlling reaction.

Key words: butyl xanthate; electrocatalytic; internal micro-electrolysis; degradation mechanism; pathway